Dynamics of elastic, nonheavy spheres sedimenting in a rectangular duct

Understanding of sedimentation dynamics of particles in bounded fluids is of crucial importance for a wide variety of processes. While there is profound knowledge base regarding the sedimentation of rigid solid particles, the fundamental principles of sedimentation dynamics of elastic, nonheavy sphe...

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Bibliographic Details
Published in:arXiv.org 2021-05
Main Authors: Behrendt, Isabell, Schoenecker, Clarissa
Format: Article
Language:English
Subjects:
Acceleration
Computational fluid dynamics
Deformation effects
Elastic deformation
Fluid flow
Formability
Knowledge bases (artificial intelligence)
Reynolds number
Sedimentation
Sedimentation & deposition
Spheres
Terminal velocity
Velocity
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Summary:Understanding of sedimentation dynamics of particles in bounded fluids is of crucial importance for a wide variety of processes. While there is profound knowledge base regarding the sedimentation of rigid solid particles, the fundamental principles of sedimentation dynamics of elastic, nonheavy spheres in bounded fluids are not well understood. Therefore, we performed sedimentation of deformable, elastic solid spheres with particle Reynolds numbers much smaller than 1 in a model experiment. The spheres started from rest in a rectangular duct with a width of about 23 times the radius R of the sphere. The particle dynamics of elastic spheres differed fundamentally from that of rigid spheres. Elastic effects were found to take place on comparatively large time scales, such that elastic spheres underwent four phases of sedimentation. Phases I and II, including transient acceleration and a short steady velocity plateau, are comparable with sedimentation of rigid spheres. From a characteristic onset position of about 10R, deformability effects kick in and a second acceleration appears (phase III). In the fourth phase, the deformable spheres reach the terminal sedimentation velocity. The softer the spheres are, the higher the terminal velocity is. In the present setup, a terminal velocity up to 9 percent higher than the velocity for comparable rigid spheres was reached. By means of the obtained data, insights into the dynamics are given that could serve as basic approaches for modelling the dynamics of elastic spheres in bounded fluids.
ISSN:2331-8422
DOI:10.48550/arxiv.2105.13474